JP2020155987A - Radio relay device and temperature management method for radio relay device - Google Patents

Abstract

To switch a control channel considering temperature rise and prevent base station functions from going down due to abnormal temperature rise.SOLUTION: In a base station, when a state of a repeater device capable of wireless communication with a communication terminal is in a control channel state where the entire communication is controlled, a site controller determines whether or not an inside temperature of the repeater device is equal to or more than a preset first temperature threshold. When the inside temperature of the repeater device is equal to or more than the first temperature threshold, the site controller shifts a state of another repeater device in an idle state where no process is performed to the control channel state, and then shifts the state of the repeater device from the control channel state to a use prohibited state. When the inside temperature becomes equal to or less than a preset second temperature threshold and a prescribed time elapsed, the site controller shifts the state of the repeater device from the use prohibited state to the idle state.SELECTED DRAWING: Figure 2

Description

The present invention relates to a method for controlling the temperature of a wireless relay device.

A wireless communication system for providing a telecommunications service such as a mobile communication terminal is operated by installing a plurality of repeater devices at a base station. Then, one of the plurality of repeater devices becomes a repeater device (CCH) that plays a role of a control channel for notifying the communication terminal (mobile station) of the base station information, and the other is a communication channel for relaying a call. It becomes a repeater device (TCH) that plays the role of. In this method, the site controller determines the channel to be used for communication between the communication terminals, the CCH notifies the communication terminal, and the determined channel is used by the communication terminal to control the TCH. Since the CCH continuously transmits control signals as described above, the CCH prevents deterioration of the apparatus by switching roles with one of the TCHs in the idle state at that time at regular time intervals.

However, the change of roles according to the time interval has a problem that the repeater device hangs up because it cannot cope with a sudden temperature rise in the device. For example, when the repeater device of the control channel reaches an abnormal temperature (about 85 ° C.), an error is displayed and transmission is stopped without notifying the communication terminal under the system, and then the repeater device of another channel is set to the control channel. It was started as a repeater device.

This temperature rise is triggered by various factors such as changes in the ambient temperature of the repeater device, changes in the transmission output, and the number of communication terminals to be controlled, whereas the control channel switching timing is the specified time, or the specified time and constant. It was only a cycle (minimum 1 hour). For this reason, there has been a demand for a technique for preventing the repeater device from hanging up by monitoring the temperature and maintaining the call function.

For example, in Patent Document 1, in the selection of a repeater device that monitors the internal temperature of a plurality of repeater devices and plays a role of a communication channel (relay channel) for relaying a call or data communication, the relay channel is in an idle state. In addition, a technique for preventing a failure of the repeater device due to a temperature rise by selecting a repeater device having a low internal temperature is disclosed.

JP-A-2010-206259

Patent Document 1 shows an example of a method in which the operation of the control channel is not concentrated on a specific repeater device, but on the other hand, there is also a method in which the operation of the control channel is concentrated on a specific repeater device. In this case, since the repeater device that plays the role of the control channel continuously transmits the control signal, the internal temperature of the repeater device tends to rise.

Further, the method of Patent Document 1 is a technique for selecting a repeater device of a "relay channel" that is responsible for transmission / reception next, and refers to the internal temperature of another repeater device as a selection criterion. Therefore, the repeater device, which plays the role of a control channel for continuous transmission, does not measure the timing of transferring its own role. Furthermore, it is preferable not to use the repeater device whose internal temperature has risen sharply until the internal temperature returns to the normal range, and it is necessary to stop and restore the repeater device whose internal temperature has risen while maintaining the function of the base station. There is.

The present invention has been made in view of the above, and an object of the present invention is to prevent the base station function from being down due to an abnormal temperature rise.

In order to solve the above-mentioned problems and achieve the object, the wireless relay device according to the present invention has a processing unit capable of wireless communication with a communication terminal and capable of switching channel states, and a temperature for measuring temperature. The site controller includes a repeater device including a measuring unit and a site controller that manages the state of the channel (repeater device) of the base station and communication. The site controller is a control channel state in which the repeater device controls the entire communication. Further, when the internal temperature of the repeater device is equal to or higher than the first temperature threshold value, the state of the repeater device is changed from the control channel state to the use prohibited state.

Further, the site controller is not set to the control channel state and the communication channel state (during a call) and is not in the use prohibited state before the state of the repeater device is changed from the control channel state to the use prohibited state. The state of the other repeater device in the idle state is shifted to the control channel state.

In addition, the site controller controls the state of the repeater device after the repeater device notifies the mobile station that the state of the other repeater device has shifted to the control channel state and has become the repeater device in the next control channel state. Transition from the channel state to the disabled state.

Further, when the internal temperature of the repeater device in the prohibited state is equal to or lower than the second temperature threshold value and a predetermined time has elapsed since the state of the repeater device changed to the prohibited state, the site controller of the repeater device. Shift the state from the disabled state to the idle state.

Further, when a timer interrupt based on a preset timer time occurs, the site controller changes the state of the idle repeater device having the lowest internal temperature when there are idle repeater devices among the plurality of repeater devices. It may be made to shift to the control channel state.

Further, when the state of the repeater device changes, the site controller may initialize the value of the elapsed time after the state change and start a new count.

Further, the site controller may memorize the number of times the repeater device has been in the control channel state in the past and the maximum temperature at that time.

As a result, when determining the switching timing of the repeater device that handles the control channel, the internal temperature is continuously monitored, switching is performed before the internal temperature reaches an abnormal value, and the internal temperature becomes below the safe value. The repeater device can be prohibited from use until.

According to the present invention, it is possible to prevent the base station function from being down due to an abnormal temperature rise.

FIG. 1 is a schematic diagram showing an example of a configuration of a wireless communication system according to an embodiment of the present invention. FIG. 2 is a block diagram showing an example of the configuration of the base station according to the embodiment of the present invention. FIG. 3 is a block diagram showing an example of the configuration of the repeater device according to the embodiment of the present invention. FIG. 4 is a block diagram showing an example of the configuration of the site controller according to the embodiment of the present invention. FIG. 5 is a table showing an example of a pattern in which each repeater device is in a normal state. FIG. 6 is a table showing an example of a pattern in which it is detected that the internal temperature of the repeater device of the control channel has become high and approaches an abnormal temperature. FIG. 7 is a table showing an example of a pattern in which the control channel is switched to another repeater device. FIG. 8 is a table showing an example of a pattern in which the repeater device, which has been at a high temperature, is restored as the temperature drops. FIG. 9 is a flowchart showing an example of a processing flow in the temperature control process of the repeater device by the site controller. FIG. 10 is a flowchart showing an example of a processing flow in the time management process of the repeater device by the site controller.

Hereinafter, embodiments according to the present invention will be described in detail with reference to the accompanying drawings. The present invention is not limited to this embodiment. In addition, when there are a plurality of embodiments, those which are configured by combining each embodiment are also included.

[Embodiment]
The configuration of the wireless communication system according to the embodiment of the present invention will be described with reference to FIG. FIG. 1 is a schematic diagram showing an example of a configuration of a wireless communication system according to an embodiment of the present invention.

As shown in FIG. 1, the wireless communication system 1 according to the present embodiment includes a system controller 110, a router 120, a first base station 130A, a second base station 130B, a third base station 130C, and a first. Mobile station 150A-1, 2nd mobile station 150A-2, 3rd mobile station 150B-1, 4th mobile station 150B-2, 5th mobile station 150C-1, 6th mobile station 150C-2 And include.

In FIG. 1, the first service area 140A is a communication area (communication area) capable of wirelessly communicating with the first base station 130A. The second service area 140B is a communication area capable of wirelessly communicating with the second base station 130B. The third service area 140C is a communication area capable of wirelessly communicating with the third base station 130C. In the example shown in FIG. 1, in the first service area 140A, the first mobile station 150A-1 and the second mobile station 150A-2 can wirelessly communicate with the first base station 130A. In the second service area 140B, the third mobile station 150B-1 and the fourth mobile station 150B-2 can wirelessly communicate with the second base station 130B. In the third service area 140C, the fifth mobile station 150C-1 and the sixth mobile station 150C-2 can wirelessly communicate with the third base station 130C. Note that FIG. 1 shows three base stations (wireless relay devices) and six mobile stations (wireless communication terminals), but these are examples and do not limit the present invention. .. It is sufficient that at least one base station and one mobile station exist. Further, in the following, the first base station 130A to the third base station 130C may be generically referred to as a base station 130. Similarly, the first service area 140A to the third service area 140C may be generically referred to as a service area 140. Further, the first mobile station 150A-1 to the sixth mobile station 150C-2 may be generically referred to as a mobile station 150.

The system controller 110, the router 120, and the first base station 130A to the third base station 130C are connected by a network such as an IP (Internet Protocol) network. In the example shown in FIG. 1, a single system controller 110 manages a plurality of base stations from the first base station 130A to the third base station 130C via the router 120. However, this is an example, and in the present invention, a plurality of system controllers 110 may exist. Further, at least one base station from the first base station 130A to the third base station 130C may have the function of the system controller 110. That is, the system controller 110 and the base station 130 may be an integrated device. Since the router 120 is a general relay device that constitutes a network, detailed description thereof will be omitted here.

[base station]
The configuration of the base station will be described with reference to FIG. FIG. 2 is a block diagram showing an example of the configuration of the base station.

As shown in FIG. 2, the base station 130 includes a first repeater device 160-1, a second repeater device 160-2, a third repeater device 160-3, a site controller 170, and an antenna 180. It is assumed that the configuration of the base station 130 shown in FIG. 2 is common to all of the first base station 130A to the third base station 130C. Although three repeater devices are shown in FIG. 2, this is an example and does not limit the present invention. Actually, 4 or more units may be used. Further, in the following, the first repeater device 160-1 to the third repeater device 160-3 may be generically referred to as a repeater device 160. Further, the repeater device may also have the function of the site controller. That is, the site controller may be integrated with the repeater device. Actually, at least one of the plurality of repeater devices may be in a state where it also functions as a site controller. In that case, no separate site controller is needed.

The first repeater device 160-1 and the second repeater device 160-2 and the third repeater device 160-3 can each communicate wirelessly with the mobile station 150 in the service area 140 via the antenna 180. Further, the first repeater device 160-1 and the second repeater device 160-2 and the third repeater device 160-3 are each connected to the router 120 by a network such as an IP network. The site controller 170 is connected to each of the first repeater device 160-1, the second repeater device 160-2, and the third repeater device 160-3. The site controller 170 may have the function of the system controller 110. For example, the site controller 170 may communicate with each repeater device 160 of another base station 130 via the router 120 and manage these as well. Alternatively, the site controller 170 may be mounted on the system controller 110 side. That is, the system controller 110 may function as the site controller 170.

The first repeater device 160-1 and the second repeater device 160-2 and the third repeater device 160-3 are in different states (modes) and play different roles. The site controller 170 monitors the states of the first repeater device 160-1, the second repeater device 160-2, and the third repeater device 160-3, and depending on the situation, the site controller 170 of each repeater device 160. Switch states, that is, roles. Examples of the state of the repeater device 160 include "control channel", "communication channel", "idle", and "prohibition of use". The "control channel" is a state in which the repeater device 160 periodically transmits radio waves to the mobile station 150 to notify the presence of the base station 130 and provide the service area 140 by controlling the whole. .. In the control channel, since the repeater device 160 transmits radio waves to the mobile station 150 frequently or continuously, the internal temperature of the repeater device 160 tends to rise. The “communication channel” is a state in which the repeater device 160 is relaying a call (including data communication) of the mobile station 150 in the service area 140. The communication channel may be read as "relay channel". “Idle” is a state in which the repeater device 160 is not processing anything. By setting the repeater device 160 in an idle state, the repeater device 160 can be made to stand by without being loaded. "Prohibition of use" is a state in which the state of the repeater device 160 is prohibited from being transferred to the "control channel", "communication channel", and "idle", and the function of the repeater device 160 is stopped. For example, when the site controller 170 determines that it is dangerous to operate the repeater device 160 any more, the site controller 170 puts the repeater device 160 in the "prohibited use" state as an emergency measure and excludes the repeater device 160 from the selection target. By prohibiting the use of the repeater device 160, it is possible to reduce the elevated temperature. Although not shown, if a cooling mechanism (such as a cooling mechanism that is normally stopped) is installed inside each repeater device 160 or base station 130 in addition to the usual one, the site controller 170 is one of them. When the repeater device 160 of the above is put into the "prohibited use" state, the cooling mechanism installed in the repeater device 160 or the cooling mechanism installed in the base station 130 itself is activated, and the "use prohibited" state is set. The repeater device 160 may be cooled.

[Repeater device]
The configuration of the repeater device will be described with reference to FIG. FIG. 3 is a block diagram showing an example of the configuration of the repeater device.

As shown in FIG. 3, the repeater device 160 includes a network interface 161, a processing unit 162, a storage unit 163, a transmitting unit 164, a receiving unit 165, and a temperature measuring unit 166. The configuration of the repeater device 160 shown in FIG. 3 shall be common to all of the first repeater device 160-1 to the third repeater device 160-3. Although not shown, each configuration, for example, for the first repeater device 160-1, network interface 161-1, processing unit 162-1, storage unit 163-1, transmitting unit 164-1, receiving unit 165-1, temperature. It is expressed as the measuring unit 166-1. The same applies to the second repeater device 160-2 and the third repeater device 160-3.

The network interface 161 communicates information with an external device via a network such as an IP network. For example, the network interface 161 communicates information with another repeater device 160 or a site controller 170 in the base station 130. In addition, the network interface 161 performs information communication with external devices (system controller 110, other base station 130, etc.) of the base station 130 via the router 120. The network interface 161 is composed of, for example, a network adapter such as a NIC (Network Interface Card).

The processing unit 162 controls each unit of the repeater device 160. The processing unit 162 executes processing based on an external request. The processing unit 162 outputs a request, a processing result, or the like to the outside as necessary. The processing unit 162 is composed of, for example, a CPU (Central Processing Unit), a RAM (Random Access Memory), a ROM (Read Only Memory), and the like. In this case, the ROM stores a program for the CPU to control each part. The CPU controls each part of the repeater device 160 by reading a program stored in the ROM, allocating a data area in the RAM, and executing the program.

The storage unit 163 stores the data provided to the processing unit 162 and the data obtained as the processing result of the processing unit 162. Further, the storage unit 163 also stores data output to the outside by the processing unit 162 via the network interface 161 and the transmission unit 164 and the reception unit 165, and data input from the outside. The storage unit 163 is composed of, for example, an SSD (Solid State Drive), an HDD (Hard Disk Drive), an SD memory card (Secure Digital Memory Card), a flash memory, or the like. The above-mentioned RAM, ROM and the like may also be included.

The transmission unit 164 transmits radio waves to the external mobile station 150 via the antenna 180 under the control of the processing unit 162. At this time, the processing unit 162 also controls the transmission unit 164 to control the transmission output (transmission power) of the radio wave. The receiving unit 165 receives the radio wave transmitted from the external mobile station 150 via the antenna 180 and notifies the processing unit 162.

The temperature measuring unit 166 measures the temperature inside the repeater device 160 and notifies the processing unit 162. That is, the processing unit 162 monitors the temperature inside the repeater device 160 via the temperature measuring unit 166. The temperature measuring unit 166 is composed of, for example, a temperature measuring device installed inside the repeater device 160, a thermometer speed sensor, a thermometer, and other devices or devices capable of measuring the temperature. Further, the temperature measuring unit 166 monitors the radio waves transmitted from the transmitting unit 164, and estimates or evaluates the temperature change inside the repeater device 160 from the increase in the number of times the radio waves are transmitted per unit time (load increase). You can do it.

[Site controller]
The configuration of the site controller will be described with reference to FIG. FIG. 4 is a block diagram showing an example of the configuration of the site controller.

As shown in FIG. 4, the site controller 170 includes a network interface 171, a processing unit 172, and a storage unit 173. It is assumed that the configuration of the site controller 170 in FIG. 3 is common to all the site controllers 170 included in each of the first base station 130A to the third base station 130C. Although not shown, each configuration is described as, for example, the site controller 170A, the network interface 171A, the processing unit 172A, and the storage unit 173A for the first base station 130A. The same applies to the second base station 130B and the third base station 130C.

The network interface 171 communicates information with an external device via a network such as an IP network. For example, the network interface 171 communicates information with the repeater device 160 in the base station 130. Further, the network interface 171 may perform information communication with an external device (system controller 110, another base station 130, etc.) of the base station 130 via the router 120.

The processing unit 172 monitors and controls each repeater device 160 via the network interface 171. The processing unit 172 outputs a request, a processing result, or the like to the outside as necessary. The processing unit 172 is composed of, for example, a CPU, RAM, ROM, and the like. In this case, the ROM stores a program for the CPU to control each part. The CPU monitors and controls each repeater device 160 by reading a program stored in the ROM, allocating a data area in the RAM, and executing the program.

The storage unit 173 stores the data provided to the processing unit 172 and the data obtained as the processing result of the processing unit 172. Further, the storage unit 173 also stores data output to the outside by the processing unit 172 via the network interface 171 and data input from the outside. The storage unit 173 is composed of, for example, an SSD, an HDD, an SD memory card, a flash memory, or the like. The above-mentioned RAM, ROM and the like may also be included.

[Changes in state due to temperature changes]
The relationship between the change in the temperature inside the repeater device and the change in the state of the repeater device will be described with reference to FIGS. 5 to 8. FIG. 5 is an explanatory diagram showing a normal state. FIG. 6 is an explanatory diagram showing a state in which the temperature of the repeater device of the control channel is abnormal. FIG. 7 is an explanatory diagram showing a state in which the control channel is switched to another repeater device. FIG. 8 is an explanatory diagram showing the return of the repeater device that was close to the abnormal temperature.

Here, three repeater devices, a first repeater device 160-1, a second repeater device 160-2, and a third repeater device 160-3, will be described as an example. Repeater IDs of "1", "2", and "3" are assigned as identification information to each of the three repeater devices. For convenience, the repeater ID of the first repeater device 160-1 is "1", the repeater ID of the second repeater device 160-2 is "2", and the repeater ID of the third repeater device 160-3 is "3". However, "1", "2", and "3" are examples and do not limit the present invention.

In the example shown in FIG. 5, it is still in the normal state, the first repeater device 160-1 with the repeater ID “1” is in the “control channel” state, the internal temperature at this point is “50 ° C.”, and the current state. The elapsed time after the state change after becoming is "120 minutes". Further, the second repeater device 160-2 with the repeater ID "2" is in the "communication channel" state, the internal temperature at this point is "40 ° C", and the elapsed time after the state change from the current state. Is "5 minutes". For example, when the mobile station 150 starts a call, the second repeater device 160-2 shifts from the "idle" state to the "communication channel" state and relays the call of the mobile station 150 in order to relay the call. When the mobile station 150 ends the call, it shifts from the "communication channel" state to the "idle" state. Further, the third repeater device 160-3 with the repeater ID "3" is in the "idle" state, the internal temperature at this point is "30 ° C", and the elapsed time after the state change from the current state is It is "60 minutes". Specifically, the processing unit 162 of each repeater device 160 monitors the temperature inside the repeater device 160 via the temperature measuring unit 166, and the processing unit 172 of the site controller 170 via the network interface 161. , Notifies the temperature inside the repeater device 160. The processing unit 172 of the site controller 170 relates the "repeater ID", "state", "temperature (° C.)", and "elapsed time after the state change" as shown in FIG. 5 to each other and stores the storage unit 173. It may be stored in and managed.

In the example shown in FIG. 6, when 5 minutes have passed from the normal state shown in FIG. 5, the internal temperature of the first repeater device 160-1 in the “control channel” state of the site controller 170 becomes “80 ° C.”. , It is detected that the temperature is approaching an abnormal temperature. The elapsed time after the state change at this point is "125 minutes". There is no change in the second repeater device 160-2 and the third repeater device 160-3 except that 5 minutes are added to the elapsed time after the state change.

In the example shown in FIG. 7, the site controller 170 changes the state of the third repeater device 160-3 in the “idle” state from the “idle” state to the “control channel” state, and the first repeater device approaches an abnormal temperature. The state of 160-1 is changed from "control channel" to "prohibited". At this time, the elapsed time after each state change of the first repeater device 160-1 and the third repeater device 160-3 is reset, and both become "0 minutes". Specifically, the processing unit 172 of the site controller 170 determines that the temperature has approached an abnormal temperature when the internal temperature of the first repeater device 160-1 in the “control channel” state becomes “80 ° C.” or higher. A request is transmitted to the processing unit 162-3 of the third repeater device 160-3 via the network interface 171 so as to change the state of the third repeater device 160-3 from the "idle" state to the "control channel" state. To do. At the same time (or without delay thereafter), the processing unit of the first repeater device 160-1 via the network interface 171 so as to change the state of the first repeater device 160-1 from "control channel" to "prohibited use". A request is sent to 162-1. Further, the information that the state of the third repeater device 160-3 is in the "control channel" state and the state of the first repeater device 160-1 is not in the "control channel" state is sent to all the site controllers 170 in the system. You will be notified. Further, this information is broadcast from the repeater device 160 in the "control channel" state of the nearby base station 130 to the mobile station 150. The first repeater device 160-1, which is in the “prohibited” state, also shifts from the “control channel” state to the “prohibited” state after notifying the mobile station 150 of this information. The reason for first shifting the "control channel" state to another repeater device 160, notifying the mobile station 150 of the information of the other repeater device 160 in the "control channel" state, and then prohibiting the use. This is to ensure that the repeater device 160 in the "control channel" state is always secured as the base station 130 so that the operation in the "control channel" state is not interrupted, and the mobile station 150 transmits the signal in the "control channel" state. This is to guide the user to move to the repeater device 160 in the next "control channel" state without searching.

In the example shown in FIG. 8, when 5 minutes have passed from the change of the state shown in FIG. 7, the internal temperature of the first repeater device 160-1 approaching the abnormal temperature of the sight controller 170 reaches "60 ° C." After confirming that the temperature has decreased, the state of the first repeater device 160-1 is changed from the "prohibited" state to the "idle" state. Specifically, the processing unit 172 of the site controller 170 determines that the temperature can be restored when the internal temperature of the first repeater device 160-1 in the “prohibited” state becomes “60 ° C.” or less. , A request is made to the processing unit 162-1 of the first repeater device 160-1 via the network interface 171 so as to change the state of the first repeater device 160-1 from the "prohibited" state to the "idle" state. Send.

[Temperature control process]
The flow of processing in the temperature control process of the repeater apparatus by the site controller will be described with reference to FIG. It should be noted that this temperature control process shall be continuously and periodically carried out until the function of the site controller is stopped or the process is terminated.

As shown in FIG. 9, in each base station 130, the site controller 170 first determines whether or not each repeater device 160 under its control is in the "control channel" state, and the repeater device in the "control channel" state. Specify 160 (step S101). In the example shown in FIG. 5, the first repeater device 160-1 with the repeater ID “1” is in the “control channel” state.

Next, when the site controller 170 identifies the repeater device 160 in the "control channel" state (Yes in step S101), the site controller 170 confirms whether the internal temperature of the repeater device 160 in the "control channel" state is 80 ° C. or higher (step S102). ). When the internal temperature of the repeater device 160 in the "control channel" state is 80 ° C. or lower (No in step S102), nothing is done, the series of processes in the temperature control process is temporarily completed, and then a new series of processes is continued. The process is started and the process returns to the first process (returns to step S101). That is, the state of the repeater device and the internal temperature are periodically checked, and the current state is continued until the state of the repeater device 160 in the "control channel" state is switched or the internal temperature reaches 80 ° C. or higher. Here, the temperature that serves as a criterion (threshold value) for detecting that the temperature has approached an abnormal temperature due to a temperature rise is set to "80 ° C", but "80 ° C" is an example and limits the present invention. It's not a thing. The temperature that serves as the criterion (threshold value) can be set arbitrarily. That is, "80 ° C." may be read as "first temperature threshold value" (or "dangerous temperature threshold value"). However, for the purpose of not exceeding the abnormal temperature, the "first temperature threshold value" is assumed to be a temperature (smaller value) lower than the "85 ° C." estimated to be the abnormal temperature.

Next, when the internal temperature of the repeater device 160 in the "control channel" state is 80 ° C. or higher (Yes in step S102), the site controller 170 has the internal temperature of the first repeater device 160-1 in the "control channel" state. It is determined that the temperature is approaching the abnormal temperature, and the repeater device 160 currently in the “idle” state is shifted to the control channel state (step S103). When there are a plurality of repeater devices 160 in the "idle" state, the repeater device 160 in the "idle" state, which has the lowest internal temperature, is shifted to the "control channel" state. In the example shown in FIG. 6, since the internal temperature of the first repeater device 160-1 in the “control channel” state is currently “80 ° C.”, it is determined that the temperature has approached an abnormal temperature. Further, since the third repeater device 160-3 of the repeater ID "3" is in the "idle" state, the third repeater device 160-3 shifts from the "idle" state to the "control channel" state. At this time, the third repeater device 160-3 “elapsed time (minutes) after the state change” is also initialized, and the count value is reset to “0”.

At the same time (or without delay thereafter), the site controller 170 puts the repeater device 160, which is determined to have approached the abnormal temperature, into the "prohibited" state (step S104). In the example shown in FIG. 7, the first repeater device 160-1, which is determined to have approached the abnormal temperature, is shifted from the “control channel” state to the “use prohibited” state. At this time, the "elapsed time (minutes) after the state change" of the first repeater device 160-1 is also initialized, and the count value is reset to "0". Here, the series of processes in the temperature control process is temporarily completed, and then a new series of processes is started to return to the first process (return to step S101).

Further, the site controller 170 determines whether or not each of the repeater devices 160 under its control is in the "control channel" state (No in step S101) and is in the "use prohibited" state (step S105). If the repeater device 160 is neither in the "control channel" state nor in the "use prohibited" state (No in step S105), nothing is done, the series of processes in the temperature control process is temporarily terminated, and then a new series of processes is continued. Is started, and the process returns to the first process (returns to step S101).

Next, when the site controller 170 specifies the repeater device 160 in the “prohibited” state (Yes in step S105), the internal temperature of the repeater device 160 in the “prohibited” state is “60 ° C.” or less, and , It is confirmed whether or not "5 minutes" has passed since the "use prohibited" state is set (step S106). When the internal temperature of the repeater device 160 in the "prohibited use" state is higher (higher) than "60 ° C." and / or "5 minutes" has not passed since the "prohibited use" state was entered (No. in step S106). ), Do nothing, and continue the current state (return to step S101). Here, the temperature that serves as a criterion (threshold value) for detecting that recovery is possible due to a temperature drop is set to "60 ° C.", but "60 ° C." is an example and limits the present invention. is not. The temperature that serves as the criterion (threshold value) can be set arbitrarily. That is, "60 ° C." may be read as "second temperature threshold value" (or "return temperature threshold value"). However, for the convenience of determining the temperature drop, the "second temperature threshold" is assumed to be a temperature (smaller value) lower than the "first temperature threshold". Further, the elapsed time that serves as the criterion (threshold value) for the "elapsed time (minutes) after the state change" is set to "5 minutes", but "5 minutes" is an example and does not limit the present invention. The elapsed time that serves as the criterion (threshold value) can be set arbitrarily. That is, "5 minutes" may be read as "elapsed time threshold".

Next, in the site controller 170, when the internal temperature of the repeater device 160 in the "prohibited use" state is "60 ° C." or less, and "5 minutes" has elapsed from the "prohibited use" state (step). Yes) in S106, it is determined that the repeater device 160 in the "use prohibited" state can be restored due to the temperature drop, and the repeater device 160 in the "use prohibited" state is shifted to the "idle" state and restored (step S107). Here, the series of processes in the temperature control process is temporarily completed, and then a new series of processes is started to return to the first process (return to step S101). In the example shown in FIG. 8, since the internal temperature of the first repeater device 160-1 in the “use prohibited” state is “60 ° C.”, it is determined that the recovery is possible due to the temperature drop. In addition, since the first repeater device 160-1 is counted as "5 minutes" in the "elapsed time (minutes) after the state change" after the "use prohibited" state is set, the use is prohibited. It is judged that "5 minutes" have passed since then. Therefore, since the site controller 170 satisfies the above conditions, it is determined that the site controller 170 can be restored due to the temperature drop, and the first repeater device 160-1 in the "use prohibited" state is shifted to the "idle" state and restored. Let me.

As described above, it is preferable that the requirement for returning the repeater device whose use has been prohibited due to the temperature rise is not only "decrease in temperature" but also "continuation of the prohibited state for a specified time or longer". In this way, even if the temperature drops, the "use prohibited" state is continued until a certain period of time elapses, so that only a specific repeater device does not frequently rise in temperature, and the life of the repeater device is made uniform. Aim.

Further, in reality, the site controller 170 accumulates a record of "the maximum temperature when the control channel was in charge in the past" for each repeater device 160, and "the number of times the control channel was in charge in the past" and " By memorizing the "maximum temperature at that time" so that it can be known, it is possible to avoid the repeater device that frequently approaches the "abnormal temperature", or to assign it to the "communication channel" instead of the "control channel". It is also possible to make the life of the repeater device uniform by preventing only the repeater device from causing a frequent temperature rise.

[Time management process]
The flow of processing in the time management process of the repeater apparatus by the site controller will be described with reference to FIG. It should be noted that this time management process shall be continuously and periodically executed until the function of the site controller is stopped or the process is terminated.

As shown in FIG. 10, at each base station 130, the site controller 170 first detects that a timer interrupt has occurred (step S201). It is assumed that the initial value of the timer time (interrupt time) indicating the time interval for performing the timer interrupt can be arbitrarily set.

Next, the site controller 170 confirms whether or not there is an "idle" state repeater device 160 for each repeater device 160 under its control in response to the timer interrupt (step S202).

Next, when the repeater device 160 in the "idle" state is present (Yes in step S202), the site controller 170 shifts the repeater device 160 in the "idle" state to the "control channel" state (step S203). For example, in the example shown in FIGS. 5 to 8, the third repeater device 160-3 in the “idle” state is shifted to the “control channel” state. When there are a plurality of repeater devices 160 in the "idle" state, the repeater device 160 in the "idle" state, which has the lowest internal temperature, is shifted to the "control channel" state.

At the same time (or without delay thereafter), the site controller 170 shifts the repeater device 160 in the "control channel" state to the "idle" state at the time of the timer interrupt (step S204). For example, in the example shown in FIGS. 5 to 8, the first repeater device 160-1 in the “control channel” state is shifted to the “idle” state.

Next, the site controller 170 sets the first timer time as the time interval for the timer interrupt (step S205). It is assumed that the first timer time can be set arbitrarily. In this case, since the control channel has already been switched as described above, it is not necessary to hurry to switch the control channel, and the first timer time may be a normal time interval. After that, the series of processes in the time management process is temporarily completed, and then a new series of processes is started to return to the first process (return to step S201).

Further, when the repeater device 160 in the “idle” state does not exist (No in step S202), the site controller 170 sets the second timer time as the time interval for the timer interrupt (step S206). It is assumed that the second timer time can be set arbitrarily. However, in this case, since the repeater device 160 in the “idle” state does not exist and the control channel is not switched, it is necessary to hurry to switch the control channel. Therefore, the second timer time is preferably a time (smaller value) shorter than the first timer time. After that, the series of processes in the time management process is temporarily completed, and then a new series of processes is started to return to the first process (return to step S201).

As described above, in the present embodiment, the repeater device 160 notifies the site controller 170 that "the temperature has approached the abnormal temperature" and "the temperature has returned to the normal temperature". If the repeater device 160 approaching an abnormal temperature is in the "control channel" state, the site controller 170 shifts to the "use prohibited" state, prohibits the transmission of radio waves, and switches the "control channel" to another repeater device 160. ..

Further, when the site controller 170 receives a notification from the repeater device 160 in the "prohibited use" state that the temperature has returned to the normal temperature, the site controller 170 shifts the repeater device 160 from the "prohibited use" state to the "idle" state. Actually, the state may be shifted to the "communication channel" state instead of the "idle" state. If the recovery condition is further satisfied, such as when a sufficient time has passed, the state may be shifted to the "control channel" state again. The threshold value (temperature) for switching the control channel according to the temperature can be arbitrarily set by the user. The conditions for returning to the control channel are "temperature" and "elapse of a certain period of time from the time when the control channel is switched". When switching the control channel depending on the temperature, it is preferable to switch to the repeater device 160 having the lowest temperature. In the examples shown in FIGS. 5 and 6, the internal temperature of the third repeater device 160-3 in the “idle” state is “35 ° C.”, which is the lowest compared to the other repeater devices 160, so that the repeater has the lowest temperature. The device 160 is a third repeater device 160-3 in the “idle” state.

To prevent the mobile station (wireless communication terminal) under the wireless communication system from becoming hunted, when switching the control channel by temperature, as well as when switching the control channel by time, after the next control channel is activated, the current After notifying the mobile station 150 currently existing in the service area 140 of the information of the repeater device of the next control channel by the repeater device of the control channel of, the transmission of the radio wave of the repeater device of the current control channel is stopped. The factor (condition) for automatic switching of the control channel can be arbitrarily selected by the user from "temperature" or "time and temperature" in addition to the current "time".

If the time management process is carried out at the same time as the temperature control process, it is carried out in parallel. It is also possible to carry out only the temperature control process without carrying out the time control process. On the contrary, it is possible to carry out only the time control process without carrying out the temperature control process. It is possible to select whether to implement "temperature control process only", "time control process only", or "both temperature control process and time control process" on this system.

1 Wireless communication system 110 System controller 120 Router 130 Base station 140 Service area 150 Mobile station 160 Repeater device 161 Network interface 162 Processing unit 163 Storage unit 164 Transmission unit 165 Reception unit 166 Temperature measurement unit 170 Site controller 171 Network interface 172 Processing unit 173 Memory

Claims (8)

A repeater device including a processing unit capable of wireless communication with a communication terminal and capable of switching channel states, and a temperature measuring unit for measuring temperature.
A site controller that manages the state of the repeater device is provided.
When the state of the repeater device is a control channel state for controlling the entire communication and the internal temperature of the repeater device is equal to or higher than a preset first temperature threshold value, the site controller changes the state of the repeater device. A wireless relay device characterized by shifting from a control channel state to a disabled state. The site controller is in an idle state in which the state of the repeater device is not set to the control channel state and the communication channel state and is not in the use-prohibited state before shifting from the control channel state to the use-prohibited state. The wireless relay device according to claim 1, wherein the state of the other repeater device is transferred to the control channel state. The site controller notifies the communication terminal that the state of the other repeater device has shifted to the control channel state, and then shifts the state of the repeater device from the control channel state to the disabled state. , The wireless relay device according to claim 2. In the site controller, the internal temperature of the repeater device in the prohibited state is equal to or lower than a preset second temperature threshold value, and a predetermined time has elapsed since the state of the repeater device changed to the prohibited state. The wireless relay device according to any one of claims 1 to 3, wherein the state of the repeater device is changed from the prohibited state to the idle state. When a timer interrupt based on a preset timer time occurs, the site controller has an idle repeater having the lowest internal temperature when an idle repeater device exists among a plurality of repeater devices including the repeater device. The wireless relay device according to any one of claims 1 to 4, which shifts the state of the device to the control channel state. The wireless relay according to any one of claims 1 to 5, wherein the site controller initializes the value of the elapsed time after the state change and starts counting anew when the state of the repeater device is changed. apparatus. The wireless relay device according to any one of claims 1 to 6, wherein the site controller stores the number of times the repeater device has been in the control channel state in the past and the maximum temperature at that time. Determining whether the state of the repeater device that can wirelessly communicate with the communication terminal and can switch the channel state is the control channel state that controls the whole.
When the state of the repeater device is the control channel state, monitoring the internal temperature of the repeater device and
Determining whether the internal temperature of the repeater device is equal to or higher than the preset first temperature threshold value.
A method for controlling the temperature of a wireless relay device, which comprises shifting the state of the repeater device from a control channel state to a prohibited state when the internal temperature of the repeater device is equal to or higher than the first temperature threshold value.

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